Electronic image pickup device for endoscopes

ABSTRACT

An electronic image pickup device for endoscopes is arranged so that at least two filters have mutually different transmitting wavelength ranges are inserted either alternatively or as a rotatable filter disc into an optical path of either an illuminating system or an image pickup system in order to make it possible to obtain either alternatingly or simultaneously color images produced by at least two kinds of rays having mutually different wavelength ranges.

BACKGROUND OF THE INVENTION

(a) Field of the invention

The present invention relates to an electronic image pickup device forendoscopes, which is suitable for being provided in a compact size.

(b) Description of the prior art

There have been proposed in recent years various types of electronicimage pickup devices for endoscopes using such devices a solid-stateimage sensor to serve as an image pickup device.

The above-mentioned electronic image pickup device for endoscopes usinga solid-state image sensor has such an advantage that it is capable ofpreventing the degradation of the quality of images accruing from thebreakage of those optical fibers used in an endoscope which employs animage guide formed with an optical fiber bundle, or an advantage thatthe recording, etc. of the picked-up images becomes easy. Alongtherewith, a further reduction of size and a further improvement of theresolving power of images to be picked up can be envisaged, so that suchan endoscope equipped with an image pickup device made of a solid-stateimage sensor is going to be used progressively widely from now on.

An electronic image pickup device for endoscopes of the type asmentioned above which is disclosed in, for example, Japanese UtilityModel Preliminary Publication No. Sho 61-159901 provides an apparatuscharacterized by comprising an endoscope equipped with a line-sequentialtransmission type solid-state image sensor which is disposed within theforward end portion of the endoscope to be operative so as to receive anoptical image coming from an object under observation and to convert theoptical image thereof to an electric signal, and also equipped with alight-transmitter which receives, at its light-incidence end face, thelight coming from a light source and which leads this light to alight-emitting end face thereof provided at the forward end portion ofthe endoscope to thereby illuminate the object under observation, andfurther comprising a filter disc disposed between said light source andthe light-incidence end face of said light transmitter and having,formed on a same circumferential face in an alternating fashion, alight-blocking area for blocking the light beam coming from the lightsource and also having light-beam-transmitting areas for transmissiontherethrough of at least three different kinds of color lights,respectively, whereby the apparatus is operative so that, by rotatingthe filter disc at a constant speed, said at least three different kindsof color lights will successively illuminate the object underobservation with an interval of time corresponding to the light-blockingperiod between respective such illuminations, thereby reading out duringeach light-blocking period the electric charge accumulated in saidsolid-state image sensor and converting the thus read-out electriccharge to an electric signal, to perform a display of a color image ofthe object under observation based on such electric signals. Inaddition, the apparatus is further characterized in that the opposingends of said light-transmitting areas and the diaphragm which isprovided on the light-source side away from said light transmitter areeach formed to have such a configuration that a constant time period ofpassage of the light-blocking area can be maintained during therevolutions of the filter disc for those light beam-transmitters whichcould have different diameters.

However, the above-described conventional electronic image pickup devicefor endoscopes is exclusively aimed to perform observations by the useof only visible light, and thus it has been impossible to conductobservations utilizing invisible light.

SUMMARY OF THE INVENTION

It is, therefore, a primary object of the present invention to provide,in view of the above-stated circumstances, an electronic image pickupdevice for endoscopes, which makes it possible to perform observationsunder rays of mutually different two or more wavelength ranges such asvisible light and invisible rays.

According to the present invention, the above-mentioned objected isattained by arranging two or more filters having mutually differentproperties either in alternatingly insertable fashion or rotatably inthe optical path of either the illuminating system or the image pickupsystem, to allow the observation, either alternatingly orsimultaneously, of the images formed by rays of two or more wavelengthranges.

Another object of the present invention is to provide an electrode imagepickup device for endoscopes, which is arranged to allow the observationof an object for study in the form of a color image.

Still another object of the present invention is to construct theendoscope of the above-mentioned type in as much a compact size aspossible.

According to a preferred formation of the present invention, arrangementis provided so that, between the light-incidence end of a light guideand a light source, there are disposed an infrared light removing filterand a visible light removing filter in a mutually alternatinglyinsertable fashion, whereby when the infrared light removing filter isinserted in the optical path, there is obtained a color image formed bythe visible light, whereas when the visible light removing filter isused, a false color image is obtained.

According to another preferred formation of the present invention, theabove-mentioned infrared light removing filter and visible lightremoving filter are provided on a same circumference to form a rotatablefilter, so that a color image by visible light and a false color imageby infrared light can be displayed simultaneously on two televisionmonitoring screens.

According to still another preferred formation of the present invention,arrangement is provided so that said infrared light removing filter andsaid visible ray removing filter are disposed in an alternatinglyinsertable and removable fashion in the optical path of a televisioncamera mounted on the eyepiece portion of the fiberscope of theendoscope, or that in place of the above, said rotatable filter alone isdisposed in said optical path, whereby making it possible to display acolor image by visible light and a false color image by infrared lighteither in an alternating fashion on a single TV monitoring screen, orsimultaneously on two separate TV monitoring screens.

These and other objects as well as the features and advantages of thepresent invention will be apparent from the following detaileddescription of the preferred embodiments when taken in conjunction withthe accompanying drawings and appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram showing the arrangement of a first embodimentof the electronic image pickup device for endoscopes according to thepresent invention.

FIG. 2 is a timing chart showing the operation of said first embodiment.

FIG. 3 is a front view of the rotatable filter of said first embodiment.

FIG. 4 is an illustration showing the spectral transmittance of therotatable filter of said first embodiment.

FIG. 5 is an illustration showing the spectral transmittance of theinfrared light removing filter and that of the visible light removingfilter of the above-mentioned embodiment.

FIG. 6 is an illustration showing the spectral transmittance of theassembled filter in case the filter of FIG. 4 is formed by a superposingtechnique.

FIG. 7 is a block diagram showing the construction of a secondembodiment.

FIG. 8 is an enlarged diagram of the essential part of said secondembodiment.

FIG. 9 is a front view of the rotatable filter of said secondembodiment.

FIGS. 10 to 12 are illustrations showing the constructions of the thirdto fifth embodiments, respectively.

FIGS. 13 to 19 are illustration showing the spectral transmittances ofvarious types of filters, respectively.

FIG. 20 is an illustration showing the arrangement of the essentialportion of a further embodiment wherein a filter disc is disposed in itstilted position relative to the optical axis.

FIG. 21 is an illustration showing the changes, toward the shortwavelength region, of the spectral transmittance obtained from theinterference filter of FIG. 20 which is tilted relative to the opticalaxis.

FIG. 22 is an illustration showing the arrangement of the essential partof a still further embodiment wherein a fluorescent light removingfilter is disposed in the optical path of the light source means so asto be tiltable relative to the optical axis.

FIG. 23 is an illustration showing the arrangement of the essential partof a yet further embodiment wherein an infrared light removing filter isdisposed in the optical path of the light source means so as to betiltable relative to the optical axis.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Description will hereunder be made of the present invention based on theillustrated embodiments.

FIG. 1 is a block diagram showing the construction of the firstembodiment of the electronic image pickup device for endoscopesaccording to the present invention. FIG. 2 is a timing chart forexplaining the operation thereof. It should be noted that three or moredifferent kinds of color lights may herein be the lights of the fourkinds of colors which are red, green, blue and yellow, or they may bethe color lights of complementary colors such as cyan, yellow, magenta,etc. The following description will be made, however, with respect tothe instance of the three kinds of color lights, i.e. red, green andblue.

In FIG. 1, reference numeral 1 denotes the forward end portion of anendoscope. At the foremost end thereof, there are disposed an objectivelens 2 and an illuminating lens 3 which are arranged in parallel. Behindthe objective lens 2 is provided a solid-state image sensor 4 of theline-sequential transfer type which converts the optical image of thereceived light to an image signal V by a drive circuit 5, and transfersthis image signal V, via a preamplifier 6, to the circuitry of the nextstage. In the background of the illuminating lens 3, there is disposed alight guide 7 formed by, for example, an optical fiber bundle. Thislight guide 7 is so arranged that an illuminating light is irradiatedonto the light-incidence end face of the light guide via a rotatablefilter 8. The illuminating light is emitted from a light source lamp 9,and after passing through a lens 10, it impinges onto the rotatablefilter 8. This illuminating light is caused to impinge onto the end faceof said light guide 7 via the filters for R (red), G (green) and B(blue) which are disposed on the filter disc 8 in successive order withan appropriate light-blocking interval interposed between theserespective color filters. The filter disc 8 has its rotary axis which iscoupled to a motor 14 via rotation-transmitting means 13. A motordriving unit 16 is controlled by a signal supplied from a revolutiondetector 15 provided on the motor 14, to keep the revolution speed ofthe motor at a constant value. Also, on the outer circumferentialportion of the filter disc 8, there are provided timing detectors 11 and12 for generating a reading-out pulse, a start pulse, etc. to therebyestablish a synchronism between such actions as the reading-out ofinformations from the solid-state image sensor 4 and the revolution ofthe filter disc 8. On the other hand, the image signal V from saidpreamplifier 6 is further passed through an amplifier 17 for itsamplification, and the resulting signal is inputted to a multiplexer 18.This multiplexer 19 is comprised of three switches SW₁, SW₂ and SW₃corresponding to the signals R, G and B, respectively, which areinputted thereto. These switches are changed-over of their connectionssuccessively with a predetermined frame cycle by gate signals SG₁, SG₂and SG₃ intended for these respective switches, which signals beingdelivered from a multiplexing gate signal generator 19 to thereby supplyto respective R, G and B frame memories 20, 21 and 22 those imagesignals which correspond to the respective colors. The respective colorsignal which have been stored in the respective frame memories are readout and synthesized and the resulting signal is displayed in color by acolor TV monitor 23. In the above-described construction, thereading-out pulse detector 11 is intended to detect the terminal endpositions of the respective filters for R, G and B which are arranged onthe filter disc 8 to be arrayed in the direction of revolution of thisfilter disc 8, and this detector is operative so as to use its detectedpulse (reading-out pulse) Pr and a signal supplied from an oscillator 24to form a reading-out gate signal Gr. This reading-out gate signal Gr isone intended for reading out, during the periods corresponding to theperiods of time in which the lights R, G and B are not irradiated ontothe solid-state image sensor 4, the image signal which has beenaccumulated in this solid-state image sensor 4. This signal, along witha signal delivered from the oscillator 24, is inputted into an ANDcircuit 26 to thereby form a reading-out clock signal CKr which, inturn, drives said driver circuit 5 whereby to convert the electriccharge accumulated in the solid-state image sensor 4 to an image signalV for each of the colors R, G and B. On the other hand, said reading-outgate signal Gr, together with a detection pulse (start pulse) suppliedfrom said start pulse detector 12 (which is intended to detect one wholerevolution of the filter disc 8), is inputted to the multiplexing gatesignal generator 19 to form gate signals SG₁, SG₂ and SG₃ intended forthe abovesaid respective switches, to thereby changeover the connectionof the multiplexer 18 so as to input an image signal to the respectiveframe memories 20, 21 and 22 for R, G and B, respectively.

With such a construction as described above, it will be noted that, forevery one revolution of the filter disc 8, one start pulse Ps isoutputted to be delivered to the multiplexing gate signal generator 19,and also, for each one whole revolution of the disc 8, three reading-outpulses Pr corresponding to the R, G and B filters, respectively, areoutputted to be sent to a reading-out gate signal generator 25. Thisreading-out gate signal generator 25 uses the signal coming from theoscillator 24 to form a reading-out gate signal Gr which is synchronouswith the reading-out pulse Pr and has a width corresponding to theperiod of time in which each of the lights R, G and B is not irradiated.Based on this period of time of the reading out gate signal Gr, thereare formed a reading-out clock signal CKr and also switching gatesignals SG₁, SG₂ and SG₃ whereby to obtain R, G and B signals which arenecessary for color display. In the illustrated reading-out gate signalGr, those hatched regions represent the periods for reading out the R, Gand B image signals, respectively. Those low-level periods located atpositions preceding the respective hatched regions represent the periodsof time in which electric charges for R, G and B signals are accumulatedin the solid-state image sensor 4 due to the irradiation of R, G and Blights. Accordingly, the switching gate signals SG₁, SG₂ and SG₃ for theR, G and B frame memories 20, 21 and 22 will be rendered to become gatesignals corresponding to the R, G and B image signal reading-outperiods, respectively.

Here, the filter disc 8 is constructed as shown in, for example, FIG. 3.That is, it is constituted by arranging, on a same circumference, thosefilters 8a, 8b and 8c which have such spectral transmittances as A, Band C shown in FIG. 4. It should be noted here that the shapes of therespective opposing end portions of the filters 8a, 8b and 8c are eachformed to have an arcuate shape to match the cross sectional shape ofthe light bundle. Numerals 27 and 28 represent an infrared lightremoving filter and a visible light removing filter which can bealternatively inserted between the light-incidence end of the lightguide 7 and the lens 10. Their spectral transmittances are as shown inFIG. 5.

The electronic image pickup device for endoscopes according to thepresent invention are arranged as described above. Accordingly, when theinfrared light removing filter 27 is inserted in the optical path, thereis obtained a color image formed by an ordinary visible light, whereaswhen the visible light removing filter 28 is inserted in the opticalpath, there is obtained a false color image formed by dividing theinfrared light range into three wavelength ranges I₁, I₂ and I₃. Asshown by a chain line in FIG. 1, arrangement may be provided so that aseparate infrared light removing filter 27' is bonded to the visiblelight removing filter 28 to thereby obtain a color image formed by avisible light and a false color image formed by an ultraviolet light.

Also, as shown by dotted lines in FIG. 1, arrangement may be made sothat the gain of the amplifier 17 is altered interlockingly with theinter-changed assembly of the infrared light removing filter 27 and thevisible light removing filter 28, to thereby perform an adjustment ofsensitivity to light. Also, the gain of the amplifier 17 may be changedfor each of the three wavelengths in the infrared range. This latterarrangement is utilized to perform compensation of the differenceoccurring in the intensity of light where the light source lamp 9 is ofthe type whose intensity of light can vary depending on the wavelengthrange as noted in case of a xenon lamp.

Also, a filter having the property as shown in FIG. 4 may be formed byvapor-deposition of an interference film, or otherwise there may beformed a filter having such a property as A of FIG. 4 by superposing afilter having such a property as A₁ in FIG. 6 upon a filter having aproperty such as A₂.

Also, as shown by dotted lines in FIG. 1, it would be better to arrangeso that the inter-changed arrangement of the filter 27 and the filter 28relative to each other is interlocked with either the objective lens 2or the image sensor 4 to shift the focal position of the solid-stateimage sensor 4 in synchronism with the change-over between theobservation under visible light and the observation under infraredlight. That is, in case of an observation under infrared light, ingeneral, the focal position shifts rearwardly as compared to theobservation under visible light. Therefore, it is only necessary toshift at least either one of the objective lens 2 and the solid-stateimage sensor 4 in a direction in which these two members are parted awayfrom each other, when the observation is switched over to that performedunder infrared light.

FIG. 7 is a block diagram showing the construction of the secondembodiment. This embodiment uses, as shown in FIG. 9, a filter disc 29which is comprised of a filter 29a having the property of the infraredlight removing filter 27, and also comprised of a filter 29b having theproperty of the visible light removing filter 28, both of these twofilters being arranged on a same circumference, and the resulting filterdisc 29 is disposed between the light-incidence end of the light guide 7and the lens 10 in such a manner as shown in FIG. 8, and this filterdisc 29 is rotated at a revolution rate of 1/2 of that of the filterdisc 8. It should be noted here that the configurations of therespective opposing end portions of these two filters 29a and 29b areeach formed in an arcuate shape to conform to the cross sectionalconfiguration and size of a light bundle.

In FIG. 7, numeral 11B represents a reading-out pulse detector for thefilter disc 29; 13B a transmitting means for coupling the rotary axis ofthe rotatable filter disc 29 to a motor 14B; 15B a revolution detectorprovided on the motor 14B; a motor driver which is controlled by asignal coming from the revolution detector 15B; 18B a multiplexer whichis comprised of three switches SW₆, SW₇ and SW₈ corresponding to theinputted signals R, G and B; 18C a duplexer comprised of two switchesSW₄ and SW₅ which are changed-over of their connections by a gate signalsupplied from a duplexing gate signal generator 19C connected to thereading-out pulse detector 11B. The two multiplexers 18 and 18B arecaused by the duplexer 18C to be operated in an alternating fashion.Numerals 20B, 21B and 22B are frame memories for other R, G and B; and23B another color TV monitor.

According to this second embodiment, it will be noted that, bychanging-over the signals which are to be delivered to the two TVmonitors 23 and 23B in synchronism with the revolution of the rotatablefilter disc 29, it is possible to simultaneously display a visible lightcolor image on the screen of one of the two TV monitors 23 and 23B,while displaying an infrared light false color image on the screen ofthe other one of these monitors.

FIG. 10 shows the construction of a third embodiment, which is such thata TV camera 31 of the color-sequential system is mounted on the eyepieceportion of a fiberscope 30. This arrangement is operative in such a waythat, by alternatively inserting the infrared light removing filter 27and the visible light removing filter 28 in the optical path in the TVcamera 31, it is possible to selectively display, on the screen of theTV monitor, a visible light color image or an infrared light false colorimage. In place of the above-described arrangement of the two filters 27and 28, a rotatable filter disc 29 may be mounted for revolution asindicated by the chain line, making it possible to perform simultaneousdisplay of the visible light color image and the infrared light falsecolor image on the screens of the two TV monitors, respectively, as inthe case of the second embodiment shown in FIG. 7.

It should be noted here that, in place of the fiberscope 30, a rigidlens assembly may be used. Also, jointly with the solid-state imagesensor 4, a second solid-state image sensor 4' having a differentlight-sensitive wavelength range may be disposed also within the camerain such a way that these two image sensors 4 and 4' are to bealternatively inserted in the optical path thereof. In such an instance,a convenience is obtained from the provision of an arrangement allowingslidable movement of these image sensors in the camera.

FIG. 11 shows the construction of a fourth embodiment. This instantembodiment shows an electronic endoscope of the color image pickupsystem, being equipped with a rotatable filter disc 29 which performschangeover between visible light and infrared light as shown in FIG. 9,and using, on the light-incidence face side, a solid-state image sensor33 having a color-separating mozaic filter 32 (for the simultaneoussystem) to serve as an image pickup means. This mozaic filter 32 has aspectral transmittance as shown in FIG. 4. Numerals 17B and 17Crepresent amplifiers; 20B and 20C memories; 23B and 23C color TVmonitors. By using this device in such a way that the revolution of therotatable filter disc 29 is detected to thereby effect changeoverbetween two signal processing systems by means of the switches SW₁ andSW₂ in synchronism with the changeover occurring between visible lightand infrared light, it is possible to perform simultaneous display ofthe visible ray image and the infrared ray image in a manner similar tothat of the instance shown in FIG. 7.

As the signal processing circuitry, those which are employed in ordinaryone-CCD (charge-coupled device) color cameras can be utilized in therespective constituent systems without requiring any modificationthereof. It should be noted there that the memories which are to be usedin this instance have no such function as to synchronize the imagesignals of respective colors which are obtained sequentially as in thecase of areasequential color television system. Instead, this circuitryneed only to possess the function of holding the image throughout theinterval of time required for the change of timing between the imagesensor and the CRT and up to the arrival of the next image signal.

FIG. 12 shows the construction of a fifth embodiment. This embodiment issuch that a rotatable filter disc 29 similar to that shown in FIG. 11 isdisposed within either a 3-CCD TV camera or a 3-tube TV camera 35.Numeral 36 represents a three-color spectroscopic prism; 37 asolid-state image sensor or an image pickup tube; and 39 an ocular lens.Numerals 17A to 17F represent amplifiers provided to render the gainsfor respective colors to be variable. Numerals 20A to 20F representmemories. The first dichroic mirror of the three-color spectroscopicprism 36 possesses such a reflection property as shown in FIG. 4A. Thesecond dichroic mirror thereof which transmits therethrough those raysother than that has the reflection property as shown in FIG. 4B andtransmits these other rays therethrough. And, in front of thesolid-state image sensor 37, there is placed a filter having such atransmittance as shown in FIG. 4C. Whereby, it becomes possible toobtain three primary color signals in the visible light range and falsecolor signals in the infrared light range as in the instance of FIG. 11.The multiplexing gate signal generator 19 functions to effect changeoverof connections between the group of switches SW₁, SW₃ and SW₅ and thegroup of switches SW₂, SW₄ and SW₆ correspondingly to the changeoverbetween visible light and infrared rays performed by the rotatablefilter disc 29. The ampliers 17A to 17F are intended to perform fineadjustment of the gains of respective color signals, and they areexactly the same in function as stated earlier. The roles of thememories 20A to 20F are identical with those shown in FIG. 11.

It should be noted here that, in case an infrared ray-visible lightchangeover filter disc (rotatable filter disc 29) is mounted on thelight source side in such a manner as shown in FIG. 11, the infraredlight generated at the object under observation will impinge onto theimage sensor even when the filter is for visible light. In case,however, this ray-changeover filter disc is provided on the image sensorside, there is performed complete changeover between visible light andinfrared light, so that the effect which is obtained will differsomewhat between these two kinds of arrangement. As such, a selectiveuse of arrangement of the ray-changeover filter discs should be madedepending on the purposes.

It should be noted here that, in place of the TV camera 35 of either the3-CCD system or 3-tube system, there may be employed either 1-CCD or1-tube type TV camera using a mozaic filter.

In the above-described respective embodiments, arrangement is providedso as to effect changeover between two kinds of images by virtue of thecombination of visible light R, G and B and infrared light I₁, I₂ andI₃. It should be noted here that the arrangement is not limited thereto,and the combinations of R, G, I₁ and B, I₂, I₃ or the combination of R,I₁, I₂ and R, I₃, G may be used also.

Also, when it is intended to perform an observation of an object havingsuch a spectral distribution as bearing a relatively steep or sharp peakat specific wavelengths λ₀ and λ₁ as in blood hemoglobin, the rotatablefilter disc 8 to be employed is set to have such properties as A₂, B₂and C₂ of FIG. 13, and a first filter having such spectral transmittancecharacteristic bearing a steep or sharp peak at specific wavelengths λ₀and λ₁ as shown in FIG. 15 is arranged to be used instead of theinfrared light removing filter 27, whereas a second filter having suchspectral transmittance characteristic sharply removing around thespecific wavelengths λ₀ and λ₁ as shown in FIG. 14 is arranged to beused instead of the visible light removing filter 28, wherein by casethe second filter is used, a substantially ordinary visible light ismade feasible, whereas in case the first filter is used, it becomespossible to make an observation under lights having wavelength λ₀ andλ₁.

In case of an observation using a fluorescent light, a filter forremoving the light for excitation having the wavelength λ₀ as shown inFIG. 16 and another filter capable of transmitting the light forexcitation therethrough but removing the visible light as shown in FIG.17 are interchangingly inserted in the optical path on the light sourceside, whereby it is possible to obtain alternating views of the colorimage of visible light and the image of fluorescent light.

Also, in case of a TV camera (including electronic mechanisms) which ismounted on an endoscope, a filter for removing fluorescent light havingwavelengths f₁ and f₂ as shown in FIG. 18 and a filter which transmitssaid fluorescent light therethrough but removes visible rays as shown inFIG. 19 are interchangingly inserted in the image pickup optical path ofthe TV camera, whereby alternating observations of the visible lightimage and the fluorescent light image can be made. Or, arrangement maybe made to that, by using the interference filter having the property ofFIG. 18 in its tilted position in the optical path relative to theoptical axis, and allowing the passage of lights having the wavelengthsλ_(f1) and λ_(f2) therethrough by shifting the nontransmittingwavelengths from λ_(f1) and λ_(f2), whereby performing observationsutilizing both of the visible light and the fluorescent ray. On theother hand, in case the filter is not tilted, rays having wavelengthsλ_(f1) and λ_(f2) are removed, so that an ordinary observation can bemade.

It should be understood here that the wavelengths λ₀, λ_(f1) and λ_(f2)may be present in whichever wavelength bands of infrared light andultraviolet light, and that the number of wavelengths which can be usedis not limited.

The technique of performing an observation of an object while alteringthe spectral characteristic, i.e. spectral transmittance, of a givenilluminating light by tilting such an interference filter as mentionedabove relative to the optical axis can be accomplished also in theembodiment shown in FIG. 1. That is, in case of an arrangement such thatthe rotatable filter 8 of FIG. 1 is set to possess such a spectraltransmittance as that shown in FIG. 13 and that this filter is arrangedat right angles relative to the optical axis as shown in FIG. 1, anordinary color image observation of the object is feasible. However, bytilting this filter 8 relative to the optical axis as shown in FIG. 20,the spectral transmittance of the interference filter with shift towardthe short wavelength region, as indicated by A₂ ', B₂ ' and C₂ ' in FIG.21, so that an observation of a false color image in a differentwavelength range is achieved. It should be noted here that, in place ofthe filter 8, the infrared ray removing filter 27 may be tilted.Furthermore, jointly with this tilting of the filter 27, the gain of thecircuitry for each color light may be altered to thereby automaticallyregulate the balancing of the white color light impinging onto thedevice. In this latter instance, the visible light removing filter 28 isnot provided. Instead, the provision of only the infrared light removingfilter 27 is required. That is, in the device provided with a filter inthe optical path, it is only necessary to arrange the filter so as to betiltable relative to the optical axis in such a way that the filter iscapable of assuming at least two different angles relative thereto.Accordingly, in case the filter disc 8 is arranged so as to be tilted ina device of the color-sequential system, the above said filters 27 and28 may both be omitted. Furthermore, in the device of the simultaneoussystem using a mozaic filter, there may be disposed a filter having aspecial transmitting wavelength range (e.g. an infrared light removingfilter) so as to be tiltable relative to the optical axis. And, in thesedevices, also which are designed so as to tilt the filter, it is needlesto say that a fiberscope may be formed with the illuminating system andthe objective lens, and that an image pickup means may be housed in a TVcamera which is mounted on the eyepiece of the fiberscope.

Description has been made with respect to the embodiments whereinrespective light-transmitting filters are arranged at an equal intervalfrom each other via a light-removing area intervening therebetween. Itshould be understood, however, that the present invention is not limitedto devices having such an arrangement of the filters as mentioned above.There may be devices wherein the filters are not arranged at an equalinterval from each other depending on the individual requirements.

What is claimed is:
 1. An electronic image pickup device for endoscopes,comprising:an illuminating system including: light source means,light-transmitting means having a light-incidence end face abutting saidlight source means and a light-emitting end face directed to an objectunder observation to irradiate a light coming from said light sourcemeans onto said object, a first filter disc rotatably disposed betweensaid light source means and said light-incidence end face of saidlight-transmitting means and having light-transmitting areas arranged ona same circumference of said disc via a light-removing area interveningbetween the respective light-transmitting areas for removing the lightcoming from said light source means for transmitting at least threedifferent color lights one after another in succession through saidlight-transmitting areas as said first filter disc is rotated; and animage pickup system disposed in association with said illuminatingsystem and including: an objective lens, image pickup means forreceiving an image of said object formed by said objective lens, andcolor image display means connected to said image pickup means forproducing a color image of said object based on an electric signalsupplied from said image pickup means, wherein: a plurality of filtershaving mutually different transmitting wavelength ranges are disposedfor alternative insertion into an optical path of either one of saidilluminating system and said image pickup system, thereby making itpossible to obtain a color image by rays of a plurality of wavelengthranges.
 2. An electronic image pickup device for endoscopes according toclaim 1, wherein:said three different color lights are red, green andblue in color.
 3. An electronic image pickup device for endoscopesaccording to claim 1, wherein:said plurality of filters are an infraredlight removing filter and a visible light removing filter which areslidably disposed between said light source means and thelight-incidence end face of said light-transmitting means.
 4. Anelectric image pickup device for endoscopes according to claim 1,wherein:said plurality of filters are comprised of an infrared lightremoving filter, and a complex filter formed by overlapping a visiblelight removing filter, and another infrared light removing filter totransmit ultraviolet light therethrough, each of said infrared lightremoving filter and said complete filter being slidably disposed betweensaid light source means and the light-incidence end face of saidlight-transmitting means.
 5. An electronic image pickup device forendoscopes according to claim 3 or 4, wherein:said image pickup systemfurther comprises an amplifier connected to said image pickup system inassociation with said plurality of filters and being variable of itsgain interlockingly with an insertion of said infrared light removingfilter, said visible light removing filter or said complex filter intosaid optical path.
 6. An electronic image pickup device for endoscopesaccording to claim 3 or 4, wherein:said image pickup means is movablyprovided along said optical path in association with said plurality offilters, and arranged to move said image pickup means interlockinglywith the insertion, into said optical path, of either said infraredlight removing filter, said visible light removing filter or saidcomplex filter in order to bring the light-receiving face of said imagepickup means into the focusing position of an image produced by visiblelight, infrared ray or ultraviolet ray.
 7. An electronic image pickupdevice for endoscopes according to claim 3, wherein:said objective lensis provided to be movable along said optical path and is movedinterlockingly with an insertion, into said optical path, of saidinfrared light removing filter or said visible light removing filter inorder to bring the light-receiving face of said image pickup means intoa focusing position of an image produced by visible light or infraredlight.
 8. An electronic image pickup device for endoscopes according toclaim 4, wherein:said objective lens is provided to be movable alongsaid optical path and is moved interlockingly with an insertion, intosaid optical path, of said infrared ray removing filter, said visibleray removing filter or said complex filter in order to bring thelight-receiving face of said image pickup means into a focusing positionof an image produced by visible ray, infrared ray or ultraviolet ray. 9.An electronic image pickup device for endoscopes according to claim 1,wherein:said plurality of filters are comprised of an infrared lightremoving filter and a visible ray removing filter, said infrared lightremoving filter and said visible light removing filter are disposed viaa light-removing area intervening between the respective filters, on asame circumference of a second filter disc rotatably disposed betweensaid light source means and said lighttransmitting means, said secondfilter disc is arranged to be rotated at a revolution speed which is 1/2of that of said first filter disc, and said color image display means isconstituted by a pair of color TV monitoring means and is coupled tosaid image pickup means via a pair of switch means which are changedover of their connections interlockingly with a revolution of saidsecond filter disc, whereby by operating said pair of switch means insynchronism with the revolutions of said second filter disc, there canbe obtained simultaneously a visible light color image and an infraredlight false color image via said pair of color TV monitoring means. 10.An electronic image pickup device for endoscopes according to claim 1,wherein:said objective lens is built in a distal end of said endoscope,said endoscope is provided with an image guide fiber bundle receiving onits one end face the object image formed by said objective lens, and aneyepiece for observing the other end face of said image guide fiberbundle, said image pickup means is housed within a TV camera detachablyattached on the light emitting side of said eyepiece and is adapted toreceive the object image transmitted by said image guide fiber bundlethrough said eyepiece, and said plurality of filters are an infraredlight removing filter and a visible light removing filter which areslidably disposed in the foreground of said image pickup means withinsaid TV camera.
 11. An electronic image pickup device for endoscopesaccording to claim 1, wherein:said objective lens is built in a distalend of said endoscope, said endoscope is provided with an image guidefiber bundle receiving on its one end face the object image formed bysaid objectives lens, and an eyepiece for observing the other end faceof said image guide fiber bundle, said image pickup means is housedwithin a TV camera detachably attached on the light emitting side ofsaid eyepiece and is adapted to receive the object image transmitted bysaid image guide fiber bundle through said eyepiece, said plurality offilters are an infrared light removing filter and a visible removingfilter which are disposed via a light-removing area interveningtherebetween on a same circumference of a second filter disc rotatablydisposed in the foreground of said image pickup means provided withinsaid TV camera, and said second filter disc is rotated at a revolutionspeed which is 1/2 of that of said first filter disc.
 12. An electronicimage pickup device for endoscopes according to claim 10 or 11,wherein:said image pickup means is comprised of a plurality ofsolid-state image sensors which are disposed for alternative insertioninto said optical path and have mutually different light-sensitivewavelength ranges.
 13. An electronic image pickup device for endoscopeaccording to claim 1, wherein:said plurality of filters are comprised offilter removing light for excitation and a filter transmitting light forexcitation therethrough but removing visible light.
 14. An electronicimage pickup device for endoscopes according to claim 1, wherein:saidobjective lens is built in a distal end of said endoscope, saidendoscope is provided with an image guide fiber bundle receiving on itsone end face the object image formed by said objective lens, and aneyepiece for observing the other end face of said image guide fiberbundle, said image pickup means is housed with a TV camera detachablyattached on the light emitting side of said eyepiece and is adapted toreceive the object image transmitted by said image guide fiber bundlethrough said eyepiece said plurality of filters are comprised of afilter for removing fluorescent light and a filter for transmittingfluorescent light therethrough but removing visible, light both of whichfilters being slidably disposed in the foreground of said image pickupmeans housed in said TV camera.
 15. An electronic image pickup devicefor endoscopes according to claim 1, wherein:said objective lens isbuilt in a distal end of said endoscope, said endoscope is provided withan image guide fiber bundle receiving on its one end face the objectimage formed by said objective lens, and an eyepiece for observing theother end face of said image guide fiber bundle, said image pickup meansis housed with a TV camera detachably attached on the light emittingside of said eyepiece and is adapted to receive the object imagetransmitted by said image guide fiber bundle through said eyepiece, saidplurality of filters are comprised of a filter removing fluorescentlight and a filter transmitting fluorescent light therethrough butremoving visible rays both of which filters being arranged via alight-removing area intervening therebetween on a same circumference ofa second filter disc rotatably disposed in the foreground of said imagepickup means provided within said TV camera, and said second filter discis rotated at a revolution speed which is 1/2 of that of said firstfilter disc.
 16. An electronic image pickup device for endoscopeaccording to claim 3, wherein:said image pickup system further comprisesan amplifier connected to said image pickup system in association withsaid plurality of filters and being variable of its gain interlockinglywith an insertion of said infrared light removing filter or said visiblelight removing filter into said optical path, and said objective lens isbuilt in a distal end of said endoscope, said endoscope is provided withan image guide fiber bundle receiving on its one end face the objectimage formed by said objective lens, and an eyepiece for observing theother end face of aid image guide fiber bundle, said image pickup meansis housed with a TV camera detachably attached on the light emittingside of said eyepiece and is adapted to receive the object imagetransmitted by said image guide fiber bundle through said eyepiece, andsaid plurality of filters are slidably disposed in the foreground ofsaid image pickup means provided within said TV camera.
 17. Anelectronic image pickup device for endoscope according to claim 4,wherein:said image pickup system further comprising an amplifierconnected to said image pickup system in association with said pluralityof filters and being variable of its gain interlocking with an insertionof said infrared light removing filter, said visible light removingfilter or said complex filter into said optical path, said objectivelens is built in a distal end of said endoscope, said endoscope isprovided with an image guide fiber bundle receiving on its one end facethe object image formed by said objective lens, and an eyepiece forobserving the other end face of said image guide fiber bundle, saidimage pickup means is housed within a TV camera detachably attached onthe light emitting side of said eyepiece and is adapted to receive theobject image transmitted by said image guide fiber bundle through saideyepiece, and said plurality of filters including said complex filterare slidably disposed in the foreground of said image pickup meansprovided within said TV camera.
 18. An electronic image pickup devicefor endoscopes according to claim 3, wherein:said image pickup means ismovably provided along said optical path in association with saidplurality of filters, and arranged so that said image pickup means ismoved interlockingly with the insertion, into said optical path, ofeither said infrared light removing filter or said visible lightremoving filter in order to bring the light-receiving face of said imagepickup means into focusing position of an image produced by visiblelight or infrared light, said objective lens is built in a distal end ofsaid endoscope, said endoscope is provided with an image guide fiberbundle receiving on its one end face the object image formed by saidobjective lens, and an eyepiece for observing the other end face of saidimage guide fiber bundle, said image pickup means is housed with a TVcamera detachably attached on the light emitting side of said eyepieceand is adapted to receive the object image transmitted by said imageguide fiber bundle through said eyepiece, and said plurality of filtersare slidably disposed in the foreground of said image pickup meansprovided within said TV camera.
 19. An electronic image pickup devicefor endoscopes according to claim 4, wherein:said image pickup means ismovably provided along said optical path in association with saidplurality of filters, and arranged so that said image pickup means ismoved interlockingly with the insertion, into said optical path, ofeither said infrared light removing filter, said visible light removingfilter or said complex filter in order to bring the light-receiving faceof said image pickup means into the focusing position of an imageproduced by visible light, infrared light or ultraviolet light, saidobjective lens is built in a distal end of said endoscope, saidendoscope is provided with an image guide fiber bundle receiving on itsone end face the object image formed by said objective lens, and aneyepiece for observing the other end face of said image guide fiberbundle, said image pickup means is housed with a TV camera detachablyattached on the light emitting side of said eyepiece and is adapted toreceive the object image transmitted by said image guide fiber bundlethrough said eyepiece, and said complex filter is slidably disposed inthe foreground of said image pickup means provided within said TVcamera.
 20. An electronic image pickup divide for endoscopes accordingto claim 3, wherein:said objective lens is provided to be movable alongsaid optical path and is moved interlockingly with an insertion, intosaid optical path, of said infrared light removing filter or saidvisible light removing filter in order to bring the light-receiving faceof said image pickup means into a focusing position of an image producedby visible light or infrared light, said objective lens is built in adistal end of said endoscope, said endoscope is provided with an imageguide fiber bundle receiving on its one end face the object image formedby said objective lens, and an eyepiece for observing the other end faceof said image guide fiber bundle, said image pickup means is housed witha TV camera detachably attached on the light emitting side of saideyepiece and is adapted to receive the object image transmitted by saidimage guide fiber bundle through said eyepiece, and said plurality offilters are disposed slidably in the foreground of said image pickupmeans provided within said TV camera.
 21. An electronic image pickupdevice for endoscopes according to claim 4, wherein:said objective lensis provided to be movable along said optical path and is movedinterlockingly with a n insertion, into said optical path, of saidinfrared light removing filter, or said visible light removing filter orsaid complex filter in order to bring the light-receiving face of saidimage pickup means into a focusing position of an image produced byvisible light, infrared light or ultraviolet light, said objective lensis built in a distal end of said endoscope, said endoscope is providedwith an image guide fiber bundle receiving on its one end face theobject image formed by said objective lens, and an eyepiece forobserving the other end face of said image guide fiber bundle, saidimage pickup means is housed with a TV camera detachably attached on thelight emitting side of said eyepiece and is adapted to receive theobject image transmitted by said image guide fiber bundle through saideyepiece, and said complex filter is slidably disposed in the foregroundof said image pickup means provided within said TV camera.
 22. Anelectronic image pickup device for endoscopes according to claim 1,wherein:said plurality of filters are comprised of a filter removinglight for excitation and a filter transmitting light for excitationtherethrough but removing visible light, said objective lens is built ina distal end of said endoscope, said endoscope is provided with an imageguide fiber bundler receiving on its one end face with the object imageformed by said objective lens, and an eyepiece for observing the otherend face of said image guide fiber bundle, said image pickup means ishoused with a TV camera detachably attached on the light emitting sideof said eyepiece and is adapted to receive the object image transmittedby said image guide fiber bundle through said eyepiece, and saidplurality of filters are disposed in the foreground of said image pickupmeans provided within said TV camera.
 23. An electronic image pickupdevice for endoscopes according to claim 1, wherein:said plurality offilters are comprises of a filter removing light for excitation and afilter transmitting light for excitation therethrough but removingvisible light, said objective lens is built in a distal end of saidendoscope, said endoscope is provided with an image guide fiber bundlereceiving on its one end face the object image formed by said objectivelens, and an eyepiece for observing the other end face of said imageguide fiber bundle, said image pickup means is housed with a TV cameradetachably attached on the light emitting side of said eyepiece and isadapted to receive the object image transmitted by said image guidefiber bundle through said eyepiece, and said plurality of filters areslidably disposed in the foreground of said image pickup means housedwithin said TV camera.
 24. An electronic image pickup device forendoscopes, comprising:an illuminating system including: light sourcemeans, and light-transmitting means having a light-incidence end faceabutting said light source means and a light emitting end face directedto an object under observation to irradiate a light coming from saidlight source means onto said object; and an image pickup systemincluding: an objective lens, image pickup means having a color encodingfilter at its light-receiving face and receiving an image of said objectformed by said objective lens, and color image display means connectedto said image pickup means for producing a color image of said objectbased on an electric signal supplied from said image pickup means,wherein: a plurality of filters having mutually different transmittingwavelength ranges are disposed for alternative insertion into an opticalpath of either one of said illuminating system and said image pickupsystem, whereby making it possible to obtain a color image by rays of aplurality of wavelength ranges.
 25. An electronic image pickup devicefor endoscopes according to claim 24, wherein:said plurality of filtersare comprised of a filter removing light for excitation and a filtertransmitting light for excitation therethrough but removing said visiblelight.
 26. An electric image pickup device for endoscopes according toclaim 24, wherein:said objective lens is built in a distal end of saidendoscope, said endoscope is provided with an image guide fiber bundlereceiving on its one end face the object image formed by said objectivelens and transmitting the object image onto its other end face, and saidimage pickup means is adapted to receive the object image transmittedthrough said image guide fiber bundle.
 27. An electronic image pickupdevice for endoscopes, comprising:an illuminating system including:light source means, light-transmitting means having a light-incidenceend face abutting said light source means and a light-emitting end facedirected to an object under observation to irradiate a light coming fromsaid light source means onto said object, a filter disc rotatablydisposed between said light source means and said light-incidence endface of said light-transmitting means and having two filters possessingmutually different transmitting wavelength ranges and being arranged onsaid circumference via a light-removing area intervening between therespective filters; and an image pickup system disposed in associationwith said illuminating system and including: an objective lens, imagepickup means having a color encoding filter formed on itslight-receiving face and receiving an image of said object formed bysaid objective lens, a pair of switch means connected to said imagepickup means and being changed over of their connection interlockinglywith a revolution of said filter disc, and a pair of TV monitoring meansconnected to said pair of switch means, respectively, wherein: said pairof switch means are operated alternatingly in synchronism with achangeover between said two filters from one to the other which are tobe inserted into an optical path by a revolution of said filter disc,whereby realizing simultaneous display of two different kinds of colorimages produced by rays having mutually different wavelength ranges. 28.An electronic image pickup device for endoscopes according to claim 27,wherein:said two filters are comprised of an infrared light removingfilter and a visible light removing filter.
 29. An electronic imagepickup device for endoscopes, comprising:an illuminating systemincluding: light source means, and light-transmitting means having alight-incidence end face abutting said light source means and alight-emitting end face directed to an object under observation toirradiate a light coming from said light source means onto said object;an endoscope provided with with said light-transmitting means, anobjective lens and a light guide for transmitting an image of saidobject formed by said objective lens to a predetermined position; a TVcamera having: a photographic lens and a three color separating prismassembly disposed on the light emitting side of said light guide; andthree image pickup means respectively disposed to face respectivelight-emitting end faces of said prism assembly and a filter discrotatably disposed between said photographic lens and said prismassembly and having two filters possessing mutually differenttransmitting wavelength ranges and being arranged on a samecircumference of said disc via a light-removing area interveningtherebetween; three pairs of switch means connected to said image pickupmeans, respectively, and comprised of a first switch group and a secondswitch group which are arranged over of their connections interlockinglywith a revolution of said filter disc; a first color TV monitoring meansconnected to said first switch group o said three pairs of switch means;and a second color TV monitoring means connected to said second switchgroup of said three pairs of switch means, wherein: said first switchgroup and said second switch group of said three pairs of switch meansare alternating operated in synchronism with a changeover between saidtwo filters from one to the other which are to be inserted into anoptical path by a revolution of said filter disc, thereby realizing asimultaneous display of two different kinds of color images produced bylights possessing mutually different wavelength ranges.
 30. Anelectronic image pickup device for endoscopes according to claim 29,wherein:said two filters are comprised of an infrared light removingfilter and a visible light removing filter.
 31. An electronic imagepickup device for endoscopes according to claim 29, wherein:said twofilters are comprised of a filter for removing fluorescent light and afilter for transmitting fluorescent light therethrough but removingvisible light.
 32. An electronic image pickup device for endoscopes,comprising:an illuminating system including: light source means,light-transmitting means having a light-incidence end face abutting saidlight source means and a light emitting end face directed to an objectunder observation to irradiate a light coming from said light sourcemeans onto said object, a filter disc rotatably disposed between saidlight source means and said light-incidence end face of saidlight-transmitting means and having light-transmitting areas arranged ona same circumference of said disc via a light-removing area interveningbetween the respective light-transmitting areas for removing the lightcoming from said light source means for transmitting at least threedifferent color lights one after another in succession through saidlight-transmitting areas as said filter disc is rotated; and an imagepickup system disposed in association with said illuminating system andincluding: an objective lens, image pickup means for receiving an imageof said object formed by said objective lens, and color image displaymeans connected to said image pickup means for producing a color imageof said object based on an electric signal supplied from said imagepickup means, wherein: said filter disc is arranged to be tiltablerelative to an optical axis in said optical path to thereby be able toobtain a color image of said object formed by rays having a plurality ofwavelength ranges.
 33. An electronic image pickup device for endoscopesaccording to claim 32, wherein:said objective lens is built in a distalend of said endoscope, said endoscope is provided with an image guidefiber bundle receiving on its one end face the object image formed bysaid objective lens, and an eyepiece for observing the other end face ofsaid image guide fiber bundle, and said image pickup means is housedwithin a TV camera detachably attached on the light emitting side ofsaid eyepiece and is adapted to receive the object image transmitted bysaid image guide fiber bundle through said eyepiece.
 34. An electronicimage pickup device for endoscopes, comprising:an illuminating systemincluding: light source means, light-transmitting means having alight-incidence end face abutting said light source means and a lightemitting end face directed to an object under observation to irradiate alight coming from said light source means onto said object, a firstfilter disc rotatably disposed between said light source means and saidlight-incidence end face of said light-transmitting means and havinglighttransmitting areas arranged on a same circumference of said discvia a light-removing area intervening between the respectivelight-transmitting areas for removing the light coming from said lightsource means for transmitting at least three different color lights oneafter another in succession through said light-transmitting areas assaid first filter disc is rotated; and an image pickup system disposedin association with said illuminating system and including: an objectivelens, image pickup means for receiving an image of said object formed bysaid objective lens, and color image display means connected to saidimage pickup means for producing a color image of said object based onan electric signal supplied from said image pickup means, wherein: asecond filter disc having areas of specific transmitting wavelengthranges is disposed in the optical path of either said illuminatingsystem or said image pickup system, and either one of said first filterdisc and said second filter disc is arranged to be tiltable relative toan optical axis of either one of said optical paths.
 35. An electronicimage pickup divide for endoscopes according to claim 32, wherein:saidobjective lens is built in a distal end of said endoscope, saidendoscope is provided with an image guide fiber bundle receiving on itsone end face the object image formed by said objective lens, and aneyepiece for observing the other end face of said image guide fiberbundle, and said image pickup means is housed within a TV cameradetachably attached on the light emitting side of said eyepiece and isadapted to receive the object image transmitted by said image guidefiber bundle through said eyepiece.
 36. An electronic image pickupdevice for endoscopes, comprising:an illuminating system including:light source means, and light-transmitting means having alight-incidence end face abutting said light source means and alight-emitting end face directed to an object under observation toirradiate a light coming from said light source means onto said object;and an image pickup system including: an objective lens, image pickupmeans having a color encoding filter at its light-receiving face andreceiving an image of said object formed by said objective lens, andcolor image display means connected to said image pickup means forproducing a color image of said object based on an electric signalsupplied from said image pickup means, wherein: a filter having aspecific transmitting wavelength range is disposed in the optical pathof either one of said illuminating system and said image pickup system,and said filter is arranged to be tiltable relative to an optical axisof the optical path of either one of said systems.
 37. An electronicimage pickup device for endoscopes according to claim 36, wherein:saidobjective lens is built in a distal end of said endoscope, saidendoscope is provided with an image guide fiber bundle receiving on itsone end face the object image formed by said objective lens, and aneyepiece for observing the other end face of said image guide fiberbundle, and said image pickup means is housed within a TV cameradetachably attached on the light emitting side of said eyepiece and isadapted to receive the object image transmitted by said image guidefiber bundle through said eyepiece.
 38. An electrical image pickupdevice for endoscopes, comprising:an illuminating system including:light source means, light guide means receiving a light coming from saidlight source means to irradiate the light onto an object underobservation, means disposed between said light source means and saidlight guide means to enter three different color lights included in thelight coming form said light source means on after another in successioninto said light guide means; and an image pickup system disposed inassociation with said illuminating system and including: an objectivelens, image pickup means for receiving an image of said object formed bysaid objective lens, and color image display means connected to saidimage pickup means for producing a color image of said object based onan electric signal supplied from said image pickup means, wherein: aplurality of filters having mutually different transmitting wavelengthranges are disposed for alternative insertion into an optical path ofeither one of said illuminating system and said image pickup system,thereby making it possible to obtain a color image by rays of aplurality of wavelength ranges.
 39. An electronic image pickup devicefor endoscopes, comprising:an illuminating system including: lightsource means, light guide means receiving a light coming from said lightsource means to irradiate the light onto an object under observation,means disposed between said light source means and said light guidemeans to enter three different color lights included in the light comingfrom said light source means one after another in succession into saidlight guide means; and an image pickup system disposed in associationwith said illuminating system and including: an objective lens, an imageguide means transmitting an image of said object formed by saidobjective lens to a predetermined position, an image pickup meansreceiving the object image transmitted by said image guide means, andcolor image display means connected to said image pickup means forproducing a color image of said object based on an electric signalsupplied from said image pickup means, wherein: a plurality of filtershaving mutually different transmitting wavelength ranges are disposedfor alternative insertion into an optical path of either one of saidilluminating system and said image pickup system, whereby making itpossible to obtain a color image by rays of a plurality of wavelengthranges. .Iadd.
 40. An imaging apparatus comprising:an illuminating meansfor emitting illuminating light of a wavelength range including avisible range and another range other than the visible range; an imageforming optical system, disposed in association with said illuminatingmeans, for forming the image of an object to be imaged; an imaging meanshaving a sensitivity to a wavelength range ranging from a visible rangeto another range than the visible range and converting the image formedby said image forming optical system to an electric signal; a wavelengthrange dividing means dividing the wavelength range into the visiblerange and another range than the visible range to provide a plurality ofwavelength ranges; a selecting means selecting at least one wavelengthrange from among the wavelength ranges divided by said wavelength rangedividing means; and signal processing means processing the outputsignals of said imaging means, in response to said selected wavelengthranges, into video signals. .Iaddend. .Iadd.
 41. An imaging apparatuscomprising:an illuminating means for emitting illuminating light of awavelength range including a visible range and another range other thanthe visible range; an image forming optical system disposed inassociation with said illuminating means, for forming an image of anobject to be imaged; an imaging means having a sensitivity to awavelength range ranging from a visible range to the another range thanthe visible range and converting the image formed by said image formingoptical system to an electric signal; a separating means separating thewavelength range into the visible range and the other range than thevisible range and having a plurality of kinds of optical members havinga characteristic of respectively transmitting or reflecting andseparating the light of a specific wavelength range within a visibleband and another band than the visible band; a band limiting meanslimiting the separated wavelength ranges of the respective opticalmembers of said separating means to either band to select the wavelengthrange imaged by said imaging means; and a signal processing meansprocessing the output signals of said imaging means in response to thewavelength ranges selected by said band limiting means so as to be videosignals. .Iaddend. .Iadd.
 42. An imaging apparatus comprising:an imageforming optical system forming the image of an object to be imaged; animaging means having a sensitivity to a wavelength range ranging from avisible range to another range than the visible range and converting theimage formed by said image forming optical system to an electric signal;a wavelength range dividing means dividing the wavelength range of anilluminating light into a plurality of wavelength ranges within therange to which said imaging means has its sensitivity and capable ofdividing in time series the illuminating light with a combination of atleast a part of said plurality of wavelength ranges; a selecting meansselecting at least one wavelength range from among the wavelength rangesdivided by said wavelength range dividing means; and a signal processingmeans processing the output signals of said imaging means to be a videosignal in response to the wavelength range selected by said selectingmeans. .Iaddend. .Iadd.
 43. An imaging apparatus comprising:anilluminating means capable of emitting an illuminating light of awavelength range ranging from a visible range to another range than thevisible range; an image forming optical system forming the image of anobject to be imaged; an imaging means having a sensitivity to awavelength range from a visible range to another range than the visiblerange and using a solid state imaging device converting the image formedby said image forming optical system to an electric signal; a filterseparating in time series the wavelength range of the illuminating lightof said illuminating means into a plurality of wavelength ranges withinthe ranges to which said imaging means has a sensitivity and having aplurality of kinds of components filters having a transmittingcharacteristic of transmitting respectively the lights of specificwavelength ranges within a visible band and another band than thevisible band; a band limiting means limiting the transmitted wavelengthranges of the respective component filters of said filter to either bandto select the wavelength range imaged by said imaging means; and asignal processing means processing the output signals of said imagingmeans corresponding to the illuminating lights of the wavelength rangesselected by said band limiting by allotting them to respective differentcolor signals so as to be video signals. .Iaddend. .Iadd.44. An imagingapparatus according to claim 43 wherein the respective component filtersof said filter have respectively different transmitted wavelength rangeswithin the visible band and the same transmitted wavelength rangeswithin the infrared band and said band limiting means is a filtertransmitting selectively the visible band and infrared band. .Iaddend..Iadd.45. An imaging apparatus according to claim 43 wherein therespective component filters of said filter have respectively differenttransmitted wavelength ranges in the visible band and infrared band andsaid band limiting means is a filter transmitting selectively thevisible band and infrared band. .Iaddend. .Iadd.46. A method ofobserving an object image of ordinary light and an object image ofparticular light, comprising the steps of: emitting an illuminatinglight of a wavelength range ranging from a visible range to a rangeother than the visible range; dividing the illuminating light emitted bysaid step of emitting into a plurality of wavelength ranges to obtainthe object image of ordinary light or particular light; separating atleast one of the plurality of wavelength ranges by said step of dividinginto a further plurality of wavelength ranges; illuminating the lightsof the wavelength ranges separated by said step of separating to anobject; converting said object image illuminated light by said step ofilluminating into an electric signal; and imaging the electric signalobtained by said step of converting. .Iaddend. .Iadd.47. A method ofobserving an object image of ordinary light and an object image ofparticular light, comprising the steps of:emitting an illuminating lightof a wavelength range ranging from a visible range to a range other thanthe visible range; dividing the illuminating light emitted by said stepof emitting into a plurality of wavelength ranges to obtain the objectimage of ordinary light or particular light; illuminating a light of awavelength range from among the wavelength ranges divided by said stepof dividing to an object; separating the object image illuminated bysaid step of illuminating into a further plurality of images ofwavelength ranges; converting the images of the wavelength rangesseparated by said step of separating into an electric signal; andimaging the electric signal obtained by said step of converting..Iaddend. .Iadd.48. An imaging apparatus according to any one of claims40 to 45 further comprising a filter means transmitting only lightbelonging to a narrow wavelength band from among said illuminatinglight. .Iaddend.